Multi-Wrapped Virtual Private Network

ABSTRACT

The invention includes a system for transmitting multi-wrapped VPN enabled-data across a communication network from a device to another destination device within a remote protected network. The device comprises a software stack, hardware layer, application-layer VPN software, link-layer VPN software, and user-based application software. Next, the device is coupled to a communication network. Next, the system includes a link-layer VPN aggregator and an application-layer VPN aggregator. Finally, the system includes a protected network that includes the destination device. The invention includes embodiments for configuring a device to transmit multi-wrapped VPN enabled-data and processes for transmitting multi-wrapped VPN enabled-data across a communication network from a device to another destination device within a remote protected network. Finally, the invention includes inverse processes so the destination device can transmit data back through the communication network and to the device.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation to non-provisional patentapplication No. 13/850,282 filed on Mar. 25, 2013 and is related to andclaims priority from prior provisional application Ser. No. 61/616,409filed Mar. 27, 2012 the contents of which are incorporated herein byreference.

FIELD OF THE INVENTION

This invention relates generally to the field of securing data, andparticularly a method, apparatus, and system for encrypting anddecrypting electronic data from non-secure applications while in transitvia a communications network.

BACKGROUND OF THE INVENTION

People are heavily dependent on computing and communication devices tostore, process, and transmit data across a vast system of communicationnetworks. People all over the world use fixed and mobile computing andcommunication devices to perform personal and business tasks. Such usegenerates billions of data transmission each day via mobile and fixedcommunication devices such as smart phones, tablet PC's, notebook PC's,desktop PC's, or any other device that transmits data over acommunication network.

Miscreants make tremendous efforts to maliciously attack such dataduring all phases of use including storage, processing, andtransmission. Private, corporate, and government entities expendsignificant resources to protect sensitive data from malicious use.Certain government and military entities will benefit from enhancedcommercially available data encryption applications. A multi-wrapped VPNis a system that will enhance commercially available data encryptiontools, but such an invention has eluded various entities that have triedto develop a stable, successful solution.

An example where this issue is often encountered involves the use ofdevices that use the Android operating system. Android-based devices arelimited in protecting electronic data because Android-based devices havelimited virtual private network (“VPN”) capabilities. The Androidoperating system requires that users have elevated permission levelssuch as root permissions to install or operate VPN capabilities. Hence,existing VPN solutions have limited use on Android-based devices.

This invention provides a novel method, apparatus, and system to protectdata transmissions in a manner that is less cumbersome for the end userthan existing solutions. This invention enables a multi-wrapped securecommunication tunnel, or multi-wrapped VPN, on a communication devicefor secure transmissions over existing public or private communicationnetworks. This invention is also compatible with the most prolificallyused mobile communication devices and software.

BRIEF SUMMARY OF THE INVENTION

In one embodiment of the invention a system for transmittingmulti-wrapped VPN enabled-data across a communication network from adevice to a remote protected network comprises a device. The devicecomprises a software stack that may include application software,libraries, command line tools, virtual machines (“VM”), firmware, andoperating systems. Next, the device may also comprise a hardware layerincluding storage, local interfaces, and remote interfaces. Next, thedevice may also include application-layer VPN software, link-layer VPNsoftware, and other user-based application software. Next, the device iscoupled to a communication network, such as the Internet, or any otherpublic or private network. Next, the system includes a link-layer VPNaggregator and an application-layer VPN aggregator. Finally, the systemincludes a protected network that includes a destination device.

One embodiment of the invention is a process for configuring a device totransmit multi-wrapped VPN enabled-data across a communication networkcomprises installing a link-layer VPN software application to thedevice. Next the link-layer VPN software application is associated witha link-layer VPN aggregator. Next an application-layer VPN softwareapplication is installed onto the device. Next the application-layer VPNsoftware application is associated with an application-layer VPNaggregator. Finally, the device can be used to transmit data across thecommunication network with the multi-wrapped VPN.

One embodiment of the invention is a process for transmittingmulti-wrapped VPN enabled-data across a communication network from acommunication device to a remote protected network comprisestransmitting data from a local software application to anapplication-layer VPN software application. Next the application-layerVPN software encrypts the data. Next, the application-layer VPN softwaresends the encrypted data to the local network interface. Next, alink-layer VPN software application captures all data transmittedthrough the local network interface. Next, the link-layer VPN softwareencrypts all data packets leaving the device, including the data thatwas previously encrypted via the application-layer VPN software. Next,the link-layer VPN software sends the encrypted data across acommunication network. Next, a link-layer VPN aggregator is coupled tothe communication network. The link-layer VPN aggregator receives theencrypted data and inverses the encryption performed by the link-layerVPN software. Next, the link-layer VPN aggregator filters the datasending the completely decrypted data to its destination device andsends the data that was double-wrapped to the application-layer VPNaggregator. Next, the application-layer VPN aggregator receives the datathat is still encrypted and inverses the encryption performed by theapplication-layer VPN software. Next, the application-layer VPNaggregator sends the decrypted data onto the private network to thedestination device. Finally, the multi-wrapped data encryption processis reversible and the destination device can transmit data back throughthe communication network and to the device.

One embodiment of the invention is a process for transmittingmulti-wrapped VPN enabled-data across a communication network from acommunication device to a remote protected network comprising firsttransmitting data from a user-based software application to a link-layerVPN software application. The link-layer VPN software captures all dataleaving the device and encrypts the data. The link-layer VPN softwareredirects all encrypted traffic to the application-layer VPN softwareapplication via a dedicated local port. The application-layer VPNsoftware is only associated with a single local port on the networkstack. The application-layer VPN software encrypts the data a secondtime. The application-layer VPN software sends the twice-encrypted dataout of the network. The link-layer VPN software inspects the data todetermine if the source is the application-layer VPN. Alternatively, theapplication-layer VPN sends the multi-encrypted data directly to thelink-layer VPN software via a local port that detects all data incomingon the port associated with the application-layer VPN.

Next, the encrypted data is sent out of the network stack and across acommunication network. Next, a link-layer VPN aggregator is coupled tothe communication network. The link-layer VPN aggregator receives theencrypted data and inverses the encryption performed by the link-layerVPN software. Next, the link-layer VPN aggregator filters the datasending the completely decrypted data to its destination device andsends the data that was multi-wrapped to the application-layer VPNaggregator. Next, the application-layer VPN aggregator receives the datathat is still encrypted and inverses the encryption performed by theapplication-layer VPN software. Next, the application-layer VPNaggregator sends the decrypted data onto the private network to thedestination device. Finally, the double-wrapped data encryption processis reversible and the destination device can transmit data back throughthe communication network and to the device.

BRIEF DESCRIPTION OF THE DRAWINGS

Features and advantages of the claimed subject matter will be apparentfrom the following detailed description of embodiments consistenttherewith, which description should be considered with reference to theaccompanying drawings, wherein:

FIG. 1 is a diagram of an exemplary embodiment illustrating a system forestablishing a multi-wrapped VPN to transmit data across a communicationnetwork from a device to a remote protected network in accordance withthe teachings of the present invention;

FIG. 2 is a diagram of an exemplary embodiment illustrating the path formulti-wrapped VPN enabled-data compared to typical data withsingle-wrapped VPN transmitted across a communication network from adevice to a remote protected network in accordance with the teachings ofthe present invention;

FIG. 3 is a diagram of an exemplary embodiment for a process forconfiguring a device to transmit multi-wrapped VPN enabled-data across acommunication network in accordance with the teachings of the presentinvention;

FIG. 4 is a diagram of an exemplary embodiment for a process fortransmitting multi-wrapped VPN enabled-data across a communicationnetwork from a device to a remote protected network in accordance withthe teachings of the present invention;

FIG. 5 is a diagram of an exemplary embodiment for a process forreceiving multi-wrapped VPN enabled-data transmitted across acommunication network to a communication device from a remote protectednetwork in accordance with the teachings of this invention;

FIG. 6 is a diagram of an exemplary embodiment for a process to transmitmulti-wrapped VPN enabled-data across a communication network from acommunication device to a remote protected network in accordance withthe teachings of the present invention;

FIG. 7 is a diagram of an exemplary embodiment for a process forreceiving multi-wrapped VPN enabled-data transmitted across acommunication network to a communication device from a remote protectednetwork in accordance with the teachings of this invention.

DETAILED DESCRIPTION OF THE INVENTION

The following describes the details of the invention. Although thefollowing description will proceed with reference being made toillustrative embodiments, many alternatives, modifications, andvariations thereof will be apparent to those skilled in the art.Accordingly, it is intended that the claimed subject matter be viewedbroadly. Examples are provided as reference and should not be construedas limiting. The term “such as” when used should be interpreted as “suchas, but not limited to.”

FIG. 1 is a diagram of an exemplary embodiment for a system 1000 totransmit multi-wrapped VPN enabled-data across a communication network1300 from a device 1100 to a remote protected network 1600 comprising adevice 1100. The device 1100 may include a smart phone, tablet PC,notebook PC, desktop PC, remote monitoring device, camera, sensor, orany other device that transmits data across applications within thedevice, or transmits data out of the device. The device 1100 may be usedfor any type of communication, computing, or electronic operation. Theinvention is also applicable to both mobile and fixed devices sinceeither type typically includes multiple software applications thattransmit data to and from each other. Likewise mobile and fixed devicesare commonly used to transmit data to and from other mobile and fixeddevices.

Next the device 1100 comprises a hardware and software stack 1110 thatmay include user-based application software 1120, libraries 1139,command line tools 1133, virtual machines (“VM”) 1135, and operatingsystems 1137. The device 1100 may also comprise a hardware layer 1140including storage 1141, local interfaces 1143, and remote interfaces1145.

Next, the device 1100 may also include application-layer VPN software1121, link-layer VPN software 1131, and other user-based applicationsoftware 1120. The user-based application software 1120 is installedwithin the device 1100 and coupled to the device's hardware and softwarestack 1110. For example, the user-based application software 1123 isinstalled within the user space 1120 of the device's software stack andassociated with various hardware on the device 1100 such as data storage1141, local interfaces 1143, and remote interfaces 1145.

The application-layer VPN software 1121 may be installed in either root1130 or user space 1120; however it is more advantageous to exist inuser space 1120 since root, or elevated access, is not required.Applications in user space 1120 can be installed, uninstalled, updatedand configured more readily than applications installed in root space1130.

The application-layer VPN software 1121 is configured to capture alldata entering or leaving the memory space dedicated to a softwareapplication. The application-layer VPN software 1121 also includescryptographic algorithms to encrypt data leaving the memory spacededicated to a software application, or decrypt data sent to the memoryspace for use with the application. The application-layer VPN software1121 ensures that data is secure immediately upon processing by theapplication software and when stored or transferred from memory.

The link-layer VPN software 1131 typically exists in root space 1130,though it is possible to have the link-layer VPN software 1131 in theuser space 1130. The link-layer VPN software 1131 is configured tocapture all data entering or leaving the device 1100. The link-layer VPNsoftware 1131 also includes cryptographic algorithms to encrypt all dataleaving the device, or decrypt data sent to the device 1100. Thelink-layer VPN software 1121 ensures that data is secure during transitfrom the device to the communication network 1300.

Either VPN software may include a stand-alone module consisting of thenecessary algorithm, data path, and hardware and associated software.

The user-based application software 1123 may include any type ofsoftware that stores, processes, or transmits data to other applicationson the device, or to other devices such as internet browsers, email,word processing, gaming, data analysis, software applications. Theuser-based application software 1123 may also be a commerciallyavailable off-the shelf (“COTS”) software application without anintegrated data encryption capability. Such an application may includestandard software applications such as Email, SIP-based VoIP clients,web browsers, video conferencing applications, or any other softwareapplication in which communicating data across a communication networkis a function of the application.

Next, the device 1100 is coupled to a communication network 1300. Thecommunication network 1300 may be a wired or wireless communicationnetwork. The communication network 1300 may include a public or privatenetwork such as the Internet, intranet, telecommunications system, orother network capable of transmitting data.

Next, the system 1000 includes a link-layer VPN aggregator 1400 and anapplication-layer VPN aggregator 1500. Each aggregator includes acryptographic engine consisting of hardware and, or software thatutilizes a data encryption algorithm to secure data from unauthorizedaccess. The aggregators may include a stand-alone module consisting ofthe necessary memory 1430 and 1530 and control processors 1420 and 1520and application software 1410 and 1510. Likewise the aggregators may beintegrated within a server, computer, or electronic or communicationdevice.

Next, the system 1000 includes a protected network 1600. The protectednetwork 1600 may include a server such as an email-server, computer,switch, gateway, router, database server, file server, mail server,print server, web server, or other electronic or computing devicecapable of directing the data to the destination device 1700. Finally, adestination device 1700 is coupled to the protected network 1600. Thedestination device 1700 may include an electronic communication orcomputing device such as a smartphone, tablet, fixed personal computer,mobile computer, or any communication device that enables one computeror electronic device to communicate with one another.

FIG. 2 is a diagram illustrating the data path of a multi-wrapped VPNenabled-data packet 2450 compared to a single-wrapped VPN data packet2455. Data transmitted from the secure application 2100 is firstencrypted by the application-layer VPN software 2300 and then again bythe link-layer VPN software 2400 before being transmitted out of thedevice and into the communication network 2500. Next the multi-wrappedVPN enabled-data packet 2450 is received by the link-layer VPNaggregator 2600 where the link-layer VPN aggregator 2600 performs theinverse to the link-layer VPN software's encryption algorithm. Thelink-layer VPN aggregator 2600 also filters the data and sendscompletely encrypted data 2655 to the less-protected network device 2950and the once-encrypted data packet 2650 to the application-layer VPNaggregator 2700. Next the once-encrypted data packet 2650 is received bythe application-layer VPN aggregator 2700 where the application-layerVPN aggregator 2700 performs the inverse to the application-layer VPNsoftware's encryption algorithm. The application-layer VPN aggregator2700 then sends the decrypted data 2700 to the protected network 2800.

The data from the less-secured software application 2200 is transmitteddirectly to the link-layer VPN software 2400 before being sent out ofthe device and into the communication network 2500. The data from theless-secured software application 2200, however bypasses theapplication-layer VPN software 2300. Next the single-wrapped VPN datapacket 2455 is received by the link-layer VPN aggregator 2600 where thelink-layer VPN aggregator 2600 performs the inverse to the link-layerVPN software's encryption algorithm. The link-layer VPN aggregator 2600filters all of the data and sends all data completely encrypted 2655 tothe less-protected network 2500 and onto the less-protected networkdevice 2950.

This invention allows data packets from multiple software applicationsto be encrypted with different encryption levels more efficiently. Datafrom less-secured applications 2200 only need to be encrypted oncebefore leaving the device and decrypted a single time after goingthrough the communication network 2500. The less-secured data is alsoprevented from entering the protected network because it would lack theproper authentication information. This application also enables acommercial off the shelf (“COTS”) software applications and devices tobe used for more secured operations. For example, the multi-wrapped VPNenabled-data allows a COTS device to be used to transmit more secureddata using the multi-wrapped VPN technology.

FIG. 3 is a diagram of an exemplary embodiment for a process 3000 toconfigure a device to enable a multi-wrapped VPN to transmit data acrossa communication network comprising installing 3100 user-based softwareapplications on the device. Next a link-layer VPN software applicationis installed 3200 on the device. Next the link-layer VPN software isassociated and configured 3300 to a remotely located link-layer VPNaggregator. Next an application-layer VPN software application isinstalled 3400 onto the device. The application-layer VPN software isconfigured and associated 3500 with an application-layer VPN aggregator.

The VPN software applications are configured with identifyinginformation such as the communication protocols, server names, IPaddresses, remote port numbers, etc. for the associated aggregators anddevices. These configuration steps may be auto-configured on the device,or provisioned by a network administrator. Finally, the user-basedsoftware application on the device can be used to transmit 3600 dataacross the communication network with the multi-wrapped VPN.

FIG. 4 is a diagram of an exemplary embodiment for a process toestablish a multi-wrapped VPN to transmit data across a communicationnetwork from a device to a remote protected network comprisingtransmitting 4100 data from a user-based software application to anapplication-layer VPN software application. The application-layer VPNsoftware is configured to encrypt data from any of the user-basedsoftware applications that are configured to redirect all datatransmissions to the application-layer VPN software—thus making theuser-based application software a secure application. Theapplication-layer VPN software may be installed in either root or userspace; however it is more advantageous to exist in user space sinceroot, or elevated access, is not required. Applications in user spacecan be installed, uninstalled, updated and configured more readily thanapplications installed in root space. The application-layer VPN softwareis not a link-layer VPN. In other words, the application-layer VPN isassociated with specific user-based applications and does not encryptand forward all of the device's data traffic.

Next the application-layer VPN software encrypts 4200 the data includingthe destination information for the data such as a destination device'sIP address and network connection information. The data encryption isaccomplished using a data encryption process that converts a plaintextmessage into cipher text that can be decoded back into the originalmessage, such as the block or stream cipher based encryption schemes.

Next, the application-layer VPN software sends 4300 the once-encrypteddata to the local network interface. A link-layer VPN softwareapplication captures all data transmitted through the local networkinterface. The link-layer VPN software captures all data transmitted toand from the device via the local network interface. The link-layer VPNsoftware encrypts 4400 all data traffic leaving the device, includingthe data already encrypted by the application-layer VPN software. Thedata encryption is accomplished using a data encryption process thatconverts a plaintext message into cipher text that can be decoded backinto the original message, such as the block or stream cipher basedencryption schemes.

Next, the link-layer VPN software sends 4500 the twice-encrypted dataacross a communication network. The communication network may be a wiredor wireless communication network. The communication network may includea public or private network such as the Internet, intranet,telecommunications system, or other network capable of transmittingelectronic data.

Next, a link-layer VPN aggregator is coupled to the communicationnetwork. The link-layer VPN aggregator receives the twice-encrypted dataand inverses 4600 the encryption performed by the link-layer VPNsoftware. Next, the link-layer VPN aggregator filters 4700 the datasending data completely decrypted onto its destination device. Datapackets that are still encrypted are sent to the application-layer VPNaggregator. The application-layer VPN aggregator receives theonce-encrypted data and inverses 4800 the encryption performed by thelink-layer VPN software.

Each aggregator includes a cryptographic engine consisting of hardwareand, or software that utilizes a data encryption algorithm to securedata from unauthorized access. The aggregators may include a stand-alonemodule consisting of the necessary algorithm data path and a controlprocessor chips and associated software. Likewise the aggregators may beintegrated within a server, computer, or electronic or communicationdevice. The aggregators first authenticate the data as one from a knownand trusted source then it transforms the encrypted data using adecryption algorithm, or a key, to make the data readable. With thedecrypted data, the aggregators are able to identify the data's finaldestination information such as a destination device's name, IP address,port number, and device authentication information. If decryption ofauthentication fails, the encrypted data packet may be dropped.

The aggregators use the data's destination information to initiate aconnection to the next aggregator, or the protected network. The VPNaggregator coupled to the protected network will also track theconnection to the protected network and associate it with the device'sdestination information such as the IP address and local port number tofacilitate communication back to the device. Once the connection to thenext device, i.e. either the next aggregator or the protected network,is established, the aggregator sends the decrypted data to the nextintended device, either the next aggregator or the protected network.The aggregator coupled to the communication network also filters datasending data entirely decrypted to a device outside the protectednetwork and data still encrypted to the next aggregator for furtherdecryption.

Next, the application-layer VPN aggregator sends 4900 the decrypted datato the protected network for distribution to the destination device. Theprotected network may include a server such as an email-server,computer, switch, gateway, router, database server, file server, mailserver, print server, web server, or other electronic or computingdevice capable of directing the data to the destination device. Theprivate network determines the device's destination information based oninformation such as the IP address and local port number and then sends4950 the data packet onto the destination device. Finally, themulti-wrapped data encryption process is reversible and the destinationdevice can transmit data back through the communication network and tothe device.

FIG. 5 is a diagram of an exemplary embodiment for the reversibleprocess 5000 in which the destination device transmits multi-wrapped VPNenabled-data back through the communication network and to the device.This is possible because the destination device keeps track of thereturn destination information such as the original device and protectednetwork's names, IP addresses, port numbers, and authenticationinformation. Thus the destination device is able to send a decrypteddata packet, including the original device's destination information, tothe protected network. Next the protected network sends 5800 thedecrypted data from the destination device to the application VPNaggregator. Next, the application VPN aggregator receives the decrypteddata and encrypts 5700 it once then sends the once-encrypted data to thelink-layer VPN aggregator. Next, the link-Layer VPN aggregator receivesthe once-encrypted data and again encrypts 5600 the data with itsencryption algorithms. The twice-encrypted data is then sent 5600 acrossthe communication network and to the device. Next the device receivesthe twice-encrypted data and diverts all encrypted data to thelink-layer VPN software and the link-layer VPN software receives allencrypted data and inverses 5400 the link-layer VPN software encryption.The link-layer VPN software filters the data sending 5300 data to itsappropriate next destination. For example, data completely decrypted canbe sent to its associated user-based software application and data stillencrypted with the application-layer VPN software's algorithm will besent to the application-layer VPN software for further processing. Next,the application-layer VPN software receives the once-encrypted data andinverses 5200 the application-layer VPN software's encryption. Finally,the completely decrypted data is sent 5100 to the secured user-basedsoftware application.

Alternatively, in this embodiment the destination device may also beconfigured with the application-layer VPN and link-level VPN software.In this scenario, the data encryption would take place using thedestination device's own multi-wrapped VPN capability. The multi-wrappedVPN enabled-data, in this case, may still pass through the aggregatorsbut further encryption would not be necessary. An alternate path mayalso be used in which the protected network sends multi-wrapped VPNenabled-data directly to the device and thus bypassing the aggregators.

FIG. 6 is a diagram of an exemplary embodiment for a process 6000 totransmit multi-wrapped VPN enabled-data across a communication networkfrom a device 6001 to a protected network 6940. This embodiment issimilar to the embodiment described in FIG. 1-5, however the first VPNis the link-layer VPN software application 6300. This embodiment firstcomprises transmitting data from a user-based software application 6100to a link-layer VPN software application 6300. The link-layer VPNsoftware 6300 captures all data leaving the device 6001 for encryption.For example, when a user-based software application attempts to transmitdata out of the device via the network interfaces, the network filterhooks 6003 within the OS layer detects the transmission and diverts thedata to the link-layer VPN software 6300. Eventually the data getsreconnected with the transmit 6500 network filter hook 6003 and allowedto transmit via the network interfaces 6600 to the communication network6700.

After encrypting the data from secure user-based software application6100, the link-layer VPN software 6300 redirects all encrypted trafficto the application-layer VPN software application 6200 via a dedicatedlocal port. The application-layer VPN software 6200 is only associatedwith a single local port on the network stack, and unlike the link-layerVPN software 6300 it does not attempt to capture all data packets—theapplication-layer VPN software 6200 only captures data that isassociated and configured with. The application-layer VPN software 6200encrypts the data a second time. Next, the application-layer VPNsoftware 6200 attempts to send the twice-encrypted data out of thenetwork. Since the link-layer VPN software 6300 is configured tointercept all data leaving the device 6001, the link-layer VPN software6300 intercepts the data again via the network filter hooks 6003 andinspects the data to determine if the source is the application-layerVPN 6200. This is done to avoid an infinite loop in which the data wouldcontinuously transfer through the network filter hooks 6003 and throughthe link-layer VPN software 6300 and again through the application-layerVPN software 6200. When the link-layer VPN software 6300 detects thatthe data has already passed through the application-layer VPN software6200, the data is sent out through the network filter hook 6003 transmit6500 with instructions to transmit directly to the network interfaces6600 and out to the communication network 6700. Alternatively, theapplication-layer VPN 6200 may send the multi-encrypted data directly tothe link-layer VPN software 6300 via a local port that detects the dataincoming on the port that is associated with the application-layer VPN6200.

Next, a link-layer VPN aggregator 6800 is coupled to the communicationnetwork 6700. The link-layer VPN aggregator 6800 receives the encrypteddata and inverses the encryption performed by the link-layer VPNsoftware 6300. Next, the link-layer VPN aggregator 6800 filters the datasending the completely decrypted data to its destination device andsends the data that was multi-wrapped to the application-layer VPNaggregator 6900. Next, the application-layer VPN aggregator 6900receives the data that is still encrypted and inverses the encryptionperformed by the application-layer VPN software. Next, theapplication-layer VPN aggregator 6900 sends the decrypted data onto theprotected network 6940 to the destination device 6950. Each aggregatorincludes a cryptographic engine consisting of hardware and, or softwarethat utilizes a data encryption algorithm to secure data fromunauthorized access. The aggregators may include a stand-alone moduleconsisting of memory 6830, a control processor 6920, and associatedsoftware 6810. Likewise the aggregators may be integrated within aserver, computer, or electronic or communication device. The aggregatorsfirst authenticate the data as one from a known and trusted source thenit transforms the encrypted data using a decryption algorithm, or a key,to make the data readable. With the decrypted data, the aggregators areable to identify the data's final destination information such as adestination device's name, IP address, port number, and deviceauthentication information. If decryption of authentication fails, theencrypted data packet may be dropped.

The link-layer VPN aggregator 6800 uses the data's destinationinformation to initiate a connection to the application-layer VPNaggregator 6900. The application-layer VPN aggregator 6900 will alsotrack the connection to the protected network 6940 and associate withthe device's destination information such as the IP address and localport number to facilitate communication back to the device 6001. Oncethe connection to the next device, i.e. either the next aggregator orthe protected network 6940, is established, the aggregator sends thedecrypted data to the next intended device, either the next aggregatoror the protected network 6940. The link-layer VPN aggregator alsofilters data sending data entirely decrypted to a device outside theprotected network and data still encrypted to the application-layer VPNaggregator 6900 for further decryption. After decrypting the data, theapplication-layer VPN aggregator 6900 sends the data to the protectednetwork 6940.

Next, the protected network 6940 forwards the decrypted data to thedestination device 6950. Finally, the double-wrapped data encryptionprocess is reversible and the destination device 6950 can transmit databack through the communication network 6940 and to the device 6001.

FIG. 7 is a diagram of an exemplary embodiment for a process 7000 inwhich the destination device 7950 transmits multi-wrapped VPNenabled-data back through the communication network 7700 and to thedevice 7001. This is possible because the destination device 7950 keepstrack of the return destination information such as the original deviceand protected network's 7940 IP addresses and local port numbers. Thusthe destination device 7950 is able to send a decrypted data packet,including the original device's 7001 destination information, to theprotected network 7900. Next the protected network 7940 sends thedecrypted data from the destination device 7950 to the application-layerVPN aggregator 7900. Next, the application-layer VPN aggregator 7900receives the decrypted data and encrypts it once then sends theonce-decrypted data to the link-layer VPN aggregator 7800. Next, thelink-Layer VPN aggregator 7800 receives the once-decrypted data andagain encrypts the data with its encryption algorithms. Thetwice-encrypted data is then sent across the communication network 7700and on to the device 7001. Next the device 7001 receives thetwice-encrypted data via the network interfaces 7600. The data isintercepted at the capture 7400 network filter hook 7003 in the OS layerand sent to the link-layer VPN software 7300. Next the link-layer VPNsoftware 7300 receives the encrypted data and inverses the link-layerVPN aggregator software 7900 encryption. The link-layer VPN software7300 filters the data sending the data to its appropriate nextdestination. For example, data completely decrypted can be sent to itsassociated user-based software application and data still once-encryptedwith the application-layer VPN aggregator 7900 encryption algorithm willbe sent to the application-layer VPN software 7200 for furtherprocessing. Next, the application-layer VPN software 7200 receives thestill once-encrypted data and inverses the application-layer VPNaggregator 7900 encryption. Finally, the completely decrypted data isreinserted back to the capture 7400 network filter hook 7003 in the OSlayer and then on to the secured user-based software application 7100.

Alternatively, in this embodiment the destination device 7950 may alsobe configured with the application-layer VPN and link-level VPN softwareso the data encryption can take place using the destination device's7950 own multi-wrapped VPN capability. The aggregators, in this case,may still filter the multi-wrapped VPN enabled-data, but furtherencryption would not be necessary. An alternate path may also be used inwhich the protected network sends multi-wrapped VPN data directly to thedevice and thus bypassing the aggregators.

The embodiments of this invention are especially applicable to standardAndroid-based devices and software applications because Android deviceshave limited data encryption capabilities due to the need to haveelevated permissions such as root permissions to install data encryptionsoftware. This invention overcomes this issue and does not require rootpermissions to install and configure non-secure applications with dataencryption capabilities. The embodiments of this invention provide amethod and system to establish a virtual private network (“VPN”), or asecured and protected network. This invention enables user's ofAndroid-based communication devices to use COTS software applicationswithout the need to add security features to the applications. In otherwords, this invention provides secure and authenticated datatransmission from a communication device to any public or privatenetwork while using existing standard applications such as email, VoIP,internet browsers, ISR applications, video conferencing, telecommuting,inventory tracking and control, etc. This invention provides theopportunity to selectively further secure one or more existingapplications with configuration changes that can be made at theuser-space level of the software stack.

Throughout this description, references were made to components of thesystem coupled together in a manner that allows the exchange andinteraction of data, such that the operations and processes describedmay be carried out. For example, the components may be coupled withelectrical circuitry, or through wireless networks that allow thedevices to transfer data, receive power, execute the operationsdescribed, and provide structural integrity. The invention may also beenabled with more components than described in the specification. Forexample, any number and combination of devices, user-based softwareapplications, communication networks, aggregators and destinationdevices may be utilized to enable and scale out this invention.

For example, the invention may include many software applications eachassociated with a unique application-layer VPN software to encrypt anddecrypt data. Next, the many application-layer VPN software applicationsmay be associated to as few as one link-layer VPN software applicationto perform a second encryption operation on the first encrypted data.And across the communication network, each encrypted data packed may befirst decrypted by the associated unique application-layer VPNaggregator. Thus each encrypted data packet may be decrypted by one ofmany application-layer VPN aggregators and then again by a singlelink-layer VPN aggregator.

The terms and expressions, which have been employed herein, are used asterms of description and not of limitation, and there is no intention,in the use of such terms and expressions, of excluding any equivalentsof the features shown and described (or portions thereof), and it isrecognized that various modifications are possible within the scope ofthe claims. Other modifications, variations, and alternatives are alsopossible. Accordingly, the claims are intended to cover all suchequivalents.

What is claimed:
 1. A first device enabled to transmit a data set acrossa communication network comprising: a user-based application operatingon the first device, wherein the user-based application produces thedata set; an application-layer VPN application operating on the firstdevice, wherein the application-layer VPN application takes the data setand encrypts the data set producing a single-encrypted data set; alink-layer VPN application, wherein the link-layer VPN application takesthe single-encrypted data set and encrypts the single-encrypted data setto produce a twice-encrypted data set; and a local network interfacethat is enabled to send the twice-encrypted data set across thecommunication network.
 2. The first device of claim 1 wherein a capturenetwork filter hook within an OS layer of a software stack of the firstdevice detects the transmission of the data set from the user-basedapplication and diverts the data set to the link-layer VPN application.3. The first device of claim 1 wherein a transmit network filter hookcaptures the twice-encrypted data set and transmits the twice-encrypteddata set to the communication network via the local network interface.4. The first device of claim 1 wherein the application-layer VPNapplication is associated with an application-layer VPN aggregatordevice.
 5. The first device of claim 1 wherein the link-layer VPNapplication is associated with a link-layer VPN aggregator device. 6.The first device of claim 1 wherein the first device comprises a smartphone, tablet PC, notebook PC, desktop PC, remote monitoring device,camera, sensor, or any device that transmits data across applicationsoperating on the device.
 7. The first device of claim 1 wherein theuser-based application, the application-layer VPN application areinstalled within a user space of a software stack of the first devicethat does not require a root access to operate including installing,uninstalling, updating, and configuring.
 8. The first device of claim 1wherein the application-layer application is enabled to encrypt a dataset leaving a memory space of the first device dedicated to theuser-space application.
 9. The first device of claim 1 wherein thelink-layer VPN application is enabled to capture and encrypt all dataleaving the device.
 10. The first device of claim 1 wherein theuser-based application comprises an internet browser, an emailapplication, a word processing application, a gaming application, a dataanalysis application, a video conferencing application, and a softwareapplication that requires a data set to be transmitted across thecommunication network.
 11. The first device of claim 1 wherein thecommunication network includes a public or a private network includingan Internet, an intranet, a telecommunications system, and any networkcapable of transmitting a data set.
 12. A data aggregator system enabledto receive a twice-encrypted data set from a first device via acommunication network and produce a data set comprising: a link-layerVPN aggregator device enabled to take the twice-encrypted data set anddecrypt the twice-encrypted data set to produce a single-encrypted dataset; and an application-layer VPN aggregator device enabled to take thesingle-encrypted data set and decrypt the single-encrypted data set toproduce the data set.
 13. The system of claim 12 wherein thetwice-encrypted data set comprises the data set first encrypted by anapplication-layer VPN application on a first device to produce thesingle-encrypted data set and the single-encrypted data set encrypted asecond time by a link-layer VPN application on the first device toproduce the twice-encrypted data set.
 14. The system of claim 13 whereinthe data set is derived from a user-based application operating on thefirst device.
 15. A method for receiving a multi-encrypted data set froma first device and producing a decrypted data set comprising: alink-layer VPN aggregator device receiving a multi-encrypted data setfrom the first device; the link-layer VPN aggregator device decryptingthe multi-encrypted data set to produce a multi-encrypted data set withone-less-level of encryption; a set of additional link-layer VPNaggregator devices further decrypting the multi-encrypted data set withone-less-level of encryption until a single-encrypted data set isproduced; and an application-layer VPN aggregator device decrypting thesingle-encrypted data set to produce the decrypted data set.
 16. Themethod of claim 15 wherein the multi-encrypted data set comprises thedata set first encrypted by an application-layer VPN application on thefirst device to produce the single-encrypted data set and thesingle-encrypted data set encrypted a multiple number of times by a setof multiple link-layer VPN applications on the first device to producethe multi-encrypted data set.
 17. The method of claim 15 wherein thedata set is derived from a user-based application operating on the firstdevice.